Lens testing instrument



July 13, 1954 c, A, E| 2,683,392

LENS TESTING INSTRUMENT Filed Dec. 18, 1950 5 Shee'ts-Sheet 1 INVENTOR CHARLES A. ELLIS vi. BY 4 ATT ORNEY July 13, 1954 c. A. ELLIS 2,683,392

LENS TESTING INSTRUMENT Filed Dec. 18, 1950 5 Sheets-Sheet 2 I i 'l 37,

ATTORNEY y 13, 1954 c. A. ELLIS 2,683,392

LENS TESTING INSTRUMENT Filed Dec. 18, 1950 5 Sheets-Sheet 3 INVENTOR CHARLES A. ELLIS ATTORNEY July 13, 1954 c. A. ELLIS 2,633,392

LENS TESTING INSTRUMENT Filed Dec. 18, 1950 5 Sheets-Sheet 4 INVENTOR CHARLES A. ELLIS ZL EZM ATTORNEY y 3, 954 c. A. ELLIS "2,683,392

LENS TESTING INSTRUMENT 5 Sheets-Sheet 5 Filed Dec. 18, 1950 vllzgg INVENTOR CHARLES A. ELLIS AT TORNEY Patented July 13, 1954 LENS TESTING INSTRUMENT Charles A. Ellis, Southbridge, Mass., assignor to American Optical Company,

Soutlibridge,

Mass., a voluntary association of Massachusetts Application December 18, 1950, Serial No. 201,404

7 Claims.

This invention relates to instruments for use in determining the optical characteristics of lenses and has particular reference to the provision of an instrument for measuring the dioptric power and magnification of lenses either as separate or combined factors.

One of the primary objects of this invention is to provide a simple, compact, inexpensive and eifioient optical instrument. for measuring the dioptric power and magnification factors of lenses, whereby the resultant instrument will require a minimum of space and will have its operative parts conveniently located for ease of manipulation.

Another object is to provide an instrument of the above character embodying means for directing light rays along a controlled path through an article such as a lens to be tested and located at a given position relative to a fixed reference point, means for angling the lens in opposite directions in controlled amounts relative to said path, and means for measuring the range of deviation of said light rays from said controlled path as affected by said angling for the purpose of measuring the magnification characteristics of the lens. I

A further object is to provide, in an instrument of the above character, improved means for supporting an article such as a lens having toric surfaces in such a manner that one major axis of the article may be initially located in a given meridian and the said article may then be rotated ninety degrees with respect to said given meridian, said means also being adjustable longitudinally of the optical system, if desired, for permitting measurements of magnification at difierent given selected positions.

Other objects and advantages will become apparent from the following description taken in connection with the accompanying drawings, in which:

' Fig. 1 is a side elevational view of an instrument embodying the invention;

Fig. 2 is a top-plan view of the device shown in Fig. l;

f Fig. 3 is a sectional view taken on line 3-3 of Fig. 2 looking in the direction of the arrows;

Fig. 4 is a fragmentary top-plan view of the lens supporting means;

Fig. 5 is an enlarged sectional view of the telescope taken on line 5-5 of Fig. 2 looking in the direction of the arrows;

Fig. 6 is an enlarged sectional view taken on line 66 of Fig. 5 looking in the direction of the arrows;

Fig. 7 is an enlarged sectional view taken on line 'l-'! of Fig. 2 looking in the direction of the arrows;

Fig. 8 is an enlarged sectional view taken on line 88 of Fig. '7 looking in the direction of the arrows;

Fig. 9 is a front elevational view of the lens locating device;

Fig. 10 is an enlarged fragmentary vertical section taken through the center of the lens supporting device and adjacent lens locating means;

Fig. 11 is a sectional View taken on line H ll of Fig. 10 looking in the direction of the arrows;

Fig. 12 is a fragmentary rear elevational view of the lens supporting means;

Fig. 13 is an enlarged sectional view taken on line l3! 3 of Fig. 3 looking in the direction of the arrows;

Fig. 14 is an enlarged sectional View taken on line l4l4 of Fig. 1 looking in the direction of the arrows;

Fig. 15 is an enlarged fragmentary sectional view taken approximatel on line Hil5 of Fig. 1 looking in the direction of the arrows; and

Figs. 16 and 1'7 are representations of images seen by the operator when testing a lens.

The principles and theories of this invention are clearly explained in U. S. patent application No. 2,114,282 issued to A. Ames, Jr., et al. on April 19, 1938. Broadly, an instrument embodying the present invention is used for the purpose of measuring the deviations by a lens of light rays coming to the eye from various points of a field, or, in other words, to measure the amount of apparent displacement of points in a field caused by lenses interposed between the field and the eye.

A preferred embodiment of the invention is shown in the accompanying drawings wherein like characters of reference designate like parts throughout the several views. The instrument embodies a hollow base 20 to the forward end of which is adjustably connected one end of an outwardly extending upwardly curved supporting arm 2| carrying a telescope 22 at its upper end. The telescope 22 is mounted so as to be directed toward a lens supporting device 23 which is adjustably mounted on the lower end of the supporting arm 2!. Substantially coaxial with the telescope 22 on the opposite side of the lens supporting device 23 and carried by an upright portion of the rear end of the base 28 is a target holding means 24.

The telescope 22 is formed with a barrel 2 having an apertured member 26 mounted therein adjacent one end. The member 26 is positioned against shoulder formed on the inner surface of the barrel and thus positively locates an objective lens 21 which has one surface positioned in engagement therewith, as shown in Fig. 5, with a retaining ring 25 threadedly inserted in the end of the barrel 25 and enga ing the opposed surface of the objective lens 2'1 serving to retain the lens 21 and apertured member 26 in place. The opposed end of the barre is also internally threaded for reception of a threaded lens carrying ring 29 which has a reticule 30 cemented or otherwise fixedly mounted therein. The reticule 38 is provided with crossed hairlines (Fig. 6) and the ring 29 is located within the barrel 25 in such a position that the reticule 36 is spaced a predetermined distance from the objective lens 2! to provide the optical are threaded for mounting within the eyepiece barrel 32 and the retainer is apertured as at 3'! so that light may pass through the telescope to the eye of an operator.

The eyepiece barrel 32 is adapted to slide along the telescope barrel 25 so that the eyepiece lenses may be positioned as desired with respect to the telescope reticule whereby the hairlines 35 will be clearly distinguishable to the operator. Means is provided, however, for retaining the eyepiece in adjusted position and comprises a knurled operating ring 38 which encircles the eyepiece barrel 32 and is adapted to rotate there-around within a groove formed in the barrel 32. At one point within the groove the barrel is provided with a small opening 39 permitting communication between the operating ring 38 and the telescope barrel 25. Within the opening 39 is positioned a ball or roller ll} which is engaged on diametrically opposed sides by the ring 38 and telescope barrel 25, the ring 38 being provided with an inner recessed cam surface 4! into which the roller 4t extends as shown in Fig. 6. When in this position the eyepiece may be easily moved along the telescope barrel to the desired adjusted position. lockthe eyepiece in adjusted position the operator turns the knurled ring 38 which causes one or the other side of the cam surface 4! to clamp the roller 40 tightly against the telescope barrel 25, thus rendering the eyepiece immovable.

The target holding means 24 which is normally positioned in optical axial alignment with the telescope 22 comprises a longitudinally disposed target barrel A2 (Figs. 1 and 3) the ends of which are mounted within spaced ring-like upwardly extending portions 43 of the instrument base 2%.

Three spaced adjusting screws 44 are provided in each of the portions 43 for engagement with the barrel 42 so that the barrel may be assembled in aligned relation with the telescope, locking screws 45 being also provided for retaining the adjusting screws 44 in adjusted position.

A focusing ring 46 encircles the barrel 42 and is supported by a block t! (Figs. 3 and 7) which extends upwardly through a longitudinal slot 48 in the barrel 42 and is connected as by a screw it 3 and 10).

to a substantially tubular shaped slidablo memher 5!! which is fitted so as to slide longitudinally within the barrel 2 with a minimum of looseness. To rtain the slidable member in adjusted position within the barrel 32 is a tension device in the form of a leaf spring 5! which is secured as by a screw 52 to the member 53 and has portions thereof frictionally engaging the inner wall of the barrel.

The end of the slidable member which i directed toward the telescope, carries a target 53 therein. The target 53 is preferably formed a pair of transparent discs 55 (Fig. 7) placed in superimposed relation with a metal 55 therebetween, the film being removed in places t orm a transparent configuration which com. a single vertical line 55 and three spaced ho .;ontal line 5? as shown in Fig. 8.

By manually moving the iocusin; ring along the barrel t2, the operator of the instrument can adjust the target 53 with respect to the other e' merits of the optical system. The upper surface of the barrel 42 carries a longitudinal 53 (Fir. 2) and the upper portion of the focusing ring 46 carries a lens 58 having an indicator thereon for registration with the scale 53 to indicate justed position of the target 53.

The end of the target barrel nearest the telescope 22 carries a fixed retainer so into which are threaded lens carrying 5i -2 (i The rings iii and 52 each carry i speotive lens unit 53 and 64 comprising a standard lens system, the units of which are adj-u d at assembly to determine the principal focus oi the instrument. A fixed retaining ring abuts the retainer to to maintain the lerin placev The purpose of this lens system is to L by means of parallel light, an image or target 53 onto the reticule 3d, the lig it r, prociuc' the image of the target as eifected by th be tested will be more fully described hv c Adjacent the opposite end of the barre- 42 is an inclined mirror 65 which is attached as by clips 66 and screws '67 to a which is in turn attached to the base end of the barrel 52 Shown in Fig, 3.

to the base 2%) and is connected to a source of current (not shown) by sui wiring 12. The lamp 59 is positioned in a manner that rays therefrom will be reflected by the mirror 65 through the target lenses 53 all of and s4, and telescope 22 to the eyepiece which are properly spaced and a 113/ a! A lens '13 (Figs. 4 and 10) to be tested is adapted to be inserted in the optical system of the instrument between the telescope 22 and target 53. The supporting device 23 for this purpose embodies a plate 74 which is rotatably mounted on the c rer end of a pivot member '55 (Fig. 3) carried within the base 25 The plate is formed wi h localtudinal slide ways iii in which is slidahly positioned a supporting block ll having attached thereto an upright '13. The upper end portion E9 of the upright 18 is provided with an opening which is substantially concentric with the aXis of the optical system of the instrun nt in which is immovably secured a supporting ring SE (Fig. 10).

Mounted for rotation over the supporting ring 86 is a locating ring 8! which is adapted to be locked immovably to the supporting ring by means such as a thumb screw 82. A tubular retainer 83 is positioned for rotation within the supporting ring and is provided with a flange aeaasoz portion 83a. having side surface engagement with 'the adjacent end of the retainer 80 and has its peripheral surface engaging the inner surface of the locating ring 8|. A spring detent 84 is provided in the form of a stud 85 threaded into an opening through the locating ring 8| and having a longitudinal bore therein containing a coiled spring 86 which urges a ball member 81 into one or another of a series of spaced notches 88 (Fig. 11) formed in the periphery of the flange portion 83a of the retainer 93. The notches are 90 apart and thus the action of the ball member 81 when indexing with one of notches serves to indicate to the operator a 90 rotary movement.

The retainer 83 is provided with a pair of diametrically opposed longitudinal bores 89, Fig. 11, which are spaced equidistant from and parallel with the optical axis of the system and in each of which is located a slidab-le rod 99. The rods 90 are shaped to slide within the bores 89 in a direction substantially parallel with the axis of the optical system and are provided with enlarged lens engaging portions 9I of a diam- 'etergreater than the diameter of the rods 90.

The lens engaging portions 9| are slidable in portions of the bore 89 which are enlarged to receive said portions 9|. The rods 90 are each constantly urged in a direction toward the target carrying means 24 by a coiled spring 92 positioned thereover within the respective enlarged portions of the bores 89 between inner shoulders formed by the ends of the bore in which the rods 90 are slidably mounted and the inner ends of the lens engaging portions 9i.

The ends of the rods 90 which are directed toward the telescope 22 are attached as by nuts 93 or other suitable means to a disc member 94 having a knurled peripheral edge. The disc 94 can be gripped and pulled by the operator to simultaneously retract the lens engaging portions 9I of the rods 90 against the action of the springs 92 as shown in Fig. 10.

The retainer 83 is provided with a reduced threaded neck portion 95 adapted to receive a locking ring QI. Thenecx portion 95 has a plate,

95, formed with a threaded bore, secured thereto and held thereon by the locking ring 97. The plate 96 is adapted to rotate with the retainer 83 when the said retainer is rotated by turning the disc 94.

The upper edge of the plate 96 is provided with a scale 98 (Figs. 1, 2 and 4) which is adapted to register with index marks 99 provided on the upper portion I9 of the upright 18 to indicate the extent of rotary movement of the plate 96.

The lower end of the plate 96 has one end of a connecting plate I00 welded or otherwise fixedly connected thereto and extending in a direction toward the target holding means 24. The other end of the connecting plate I00 is similarly connected to the lower end of a substantially U-shaped member IN, the branches I02 of which extend upwardly and carry at their respective ends lens engaging members I03 which extend toward the plate 96 substantially equidistant from and parallel with the optical axis of the system. The members I03 and portions 9i are substantially equally spaced from the optical axis of the system and are disposed in substantially right angular relation with each other.

Thus, when the operator pulls the disc 94 to retract the rods 90, a lens 13 or similar article to be tested can be inserted between the lens engaging portions 9i and the members I03, and upon release of the disc 94 the springs 92 will urge the portions 9I into engagement with one surface of the lens I3 while the members I03 engage the opposed surface thereof to retain the lens securely in place.

The ends of the lens engaging portions 9i and lens engaging members I03 are rounded to provide four concentrically arranged points of suspension so that all conventionally shaped lenses and some specially shaped lens may be properly supported in the instrument.

The supporting plate I4 rotates about the axis of the pivot member 15 and has wide area surface engagement with the machined surface III formed on the upper face of the portion II2 of the telescope supporting arm 2|. The portion 112 is provided with a circular recess I I3 in which is located a depending portion of the plate '14. The pivot member I5 is mounted in spaced ball bearings H30. carried within a bore 4 formed in a thickened portion I I5 of the wall of "the base 20. The upper end of the portion I I5 is formed with an annular raised portion which is adapted to interfit with an annular groove formed in the adjacent surface of the end portion H2 to aid in preventing foreign matter from gaining access to the bearings I I311.

The upper end of the pivot member I5 is provided with a threaded portion N6 of reduced Oil diametrical size which extends through the portion H2 and is connected thereto by a nut Ill. The extreme end portion II8 of the threaded portion H6 extends through the plate I4, the plate 14 being rotatably connected thereto by screw and washer means H9. The pivot member 15 is provided with an enlarged integral flange I20 adjacent the junction of the threaded portion I IS with said member 75. The flange I20 is provided with a machined surface for engagement with the adjacent surface of the inner race of the upper ball bearing I I3. Thus, the arm 2! and/ or the lens supporting device 23 rotate about the axis of the pivot member I5.

In accordance with this invention, when a lens I3 is positioned in the instrument as shown in Fig. 10, its optical center is aligned with the optical axis of the device. The apex of the rear surface of the lens is then preferably located at the point of intersection of the center line of the pivot member I5 with said optical axis, which point is referred to herein as the reference point. To perform this adjustment the adjacent end of the target barrel 42 is provided with a pivoted locating member'l04 (Figs. 9 and 10) which embodies a somewhat V-shaped body having its arms I05 pivotally connected as by adjustable pivots I06 Within the end of the barrel 42. The apex of the locating member I 00 normally depends from the pivots I03 as shown by dotted lines in Fig. 10, and has secured thereto an adjustable stop I01. The locating member its is adapted to be manually swung upwardly t0 the position shown by full lines in Fig. 10 wherein the stop I01 will be located substantially on the axis of the optical system at the point where the center line of the pivot member 75 intersects said axis. A spring device is included to retain the locating member I04 in extended position and includes a ring member I08 which is fixedly mounted in the barrel 42 adjacent the lens retaining ring 60a. A coiled spring I99 engages the ring I08 at one end and at its other end is engaged by a flanged apertured disc I I0. In operation of the device, as the locating member I09 is swung upwardly, the extreme flat ends of the arms I05 thereof will engage the disc H0 and urge it farther into the barrel 42 against the tension of the spring It. Frictional engagement of the disc It with the flat ends of the arms I05 will retain the member I04 in horizontal position.

When the locating member IE4 is positioned parallel to the optical axis, the lens holding device 23 is moved longitudinally in the ways 1-5 formed in the plate 'id until the stop It! is engaged by the apex of the adjacent surface of the lens it. The block T5 is then secured in adjusted position on the base M by means such' as thumb screw I I I (Figs. 2 and 4) The member its is then moved downwardly to normal inoperative position whereupon the operator can through the telescope 22, lens l3, and lenses 63 and M to the target 53.

It is particularly pointed out that when the locating member Hit is in raised position, the distance between the end of the stop It! and the standard lens system t 36 i and the power of said standard lens system are so controlled that the dioptric power reading of the instrument. for the lens under test wil be the same as the effective dioptric power of said lens when positioned before the eye and at the standard distance from the cornea as established in the ophthalmic art. This distance is approximately 13.7 5 millimeters.

At this time the target is moved longitudinally the barrel 42 to the position where one or both sets of lines 56 and 5'! are most clearly discernible, the reading registered by the index mark 59 on scale 58 will indicate the dioptric power, if any, of the lens is in the focused meridian. When measuring the power of a lens I3 the selected lines of the image, as shown in Figs. 16 and 17, should be brought clearly into focus. In cases where the lens 13 has little or no power, both sets of the lines 55 and 5! will be visible (Fig. 16). However, in cases where a lens has different meridianal power, only the set of lines in the meridian being tested should be brought into focus, such as line 5! in Fig. 17. The above, although providing for the determination of dioptric power, is the initial step leading to the measurement only of the shape magnification of the lens.

Since the lens "it has been previously located by means of the adjustable stop It'l as described hereinhefore, so that the apex of the rear surface of the lens is located on the axis of the pivot member 75, any rotary movement of the arm 2| and the lens supporting device 23 will consequently cause rotation of the telescope 22 and lens '33 about said apex.

means for moving the arm 2i includes an extension l2! formed integral with or attached to the portion H2 of the arm 2| (Figs. '3, 14 and 15). The portion I22 of the extension I2I is provided with a transverse bore for reception of the central portion of a contactor assembly comprising a pair of spaced hardened discs I 23 and I24 having short hubs threadedly connected together as shown in Fig. 15. The hardened disc I24 is adapted to be engaged by the end of a threaded shaft I25 which is threadedly mounted for movement toward and away from the disc I24 in a retainer IE6 carried by the wall of the base 20. The shaft I25 extends through the base 2!} and the outer end. thereof carries a knob I21 whereby shaft I25 can be threaded inwardly of the base 26 to move the extension IZI and consequently the entire arm 2!. The other disc I23 is positioned within a recess formed in the end portion I22 of the extension I21 and is adapted.

to be engaged by the end portion I28 of an operating plunger I29 forming a part of an indicator device I30 which is adjustably secured onto the outside of the base 26 by means of a bracket I3I. A coiled spring I32 is mounted over the plunger I29 and has one end positioned within a retainer I33 mounted adjacent the indicator device I30, the other end of the spring I32 being positioned within the recess in the end portion I22 of the extension I2I. Thus the spring I322 constantly urges the extension IZI toward the shaft I25.

The indicator device I30 is of any conventional type wherein an indication is made of longitudinal movement of the plunger I29. The preferable type embodies a rotatable dial Itta which can be adjusted as desired with respect to an indicator I34 and locked in adjusted position by means such as a thumb screw I35. Spring mechanism (not shown) within the indicator device serves to maintain the end portion I28 of the plunger I 23 in constant engagement with the disc I23. A substantial zero location of the arm 2! is indicated by a circumferential groove I25a formed on the shaft I25 and adapted to register with the end of the retainer I26. Thus, as the knob i2! is manually rotated to adjust the position of extension I2I and consequently the arm 2 I, telescope 22, and lens l3, the adjustment will be indicated by the indicator device I30.

The lens supporting device 23 is, as has been stated, also independently adjustable about the axis of the pivot 75. This is illustrated in Fig. l wherein solid lines show the lens supporting device 25; angled to one side of the axis of the sys tem, which axis is indicated by line I35, and dot and dash lines indicate the position of the plate 14 when the device is an led to the opposite side of the axis I36.

It is to be understood, however, that the apex of the rear surface of the lens I3 always remains on the axis I36 at the point I3? where the axis I36 is intersected by the center line of the pivot member 15.

Means is provided for locating and retaining the plate i i in any one of three positions upon the arm 2! and embodies three spaced notches I38 (Figs. 3 and 13) which are formed in the under side of the plate I4 on the end thereof directed toward the operator. The notches I38 are adapted to be engaged by a beveled locating pin its which is adapted to reciprocate within a bushing hill carried in the upper side of the hollow arm 21. A spring IdI mounted over a reduced portion of the pin I39 and engaging a shoulder thereon constantly urges the pin toward the notches I38. A short lever I42, which is pivoted within the arm 2! as at N13, has one and engaging the pin I in such a manner that pivotal movement of the lever Hi2 will cause the pin I39 to move toward or away from the notches I38. This pivotal movement of the lever M2 is brought about through its engagement with the head portion I A l of a push button I i-5i which is slidably mounted within a retainer I threaded- 1y carried by thelower side of the arm I 2 I. Thus, manual operation of push button I will cause the lever I 52 to move the pin I39 downwardly out of engagement with the notches I33, and release of the push button IM will permit the spring MI to move the pin I 39 toward the notches I38.

The middle notch I3ii is adapted to automatically align the lens supporting structure with the telescope 22. The other notches I38 are so located that the pin I39 will engage them when thelens supporting device 23 is moved through an angle'of preferably either side of the optical axis I35 of the instrument. The exact spacing of the outer notches is immaterial, it being necessary, however, that they both be located at the same distance from the middle notch to permit the lens 13 to be positioned at the same angle on each side of the axis I36.

After the lens 13 has been positioned in the supporting device 23 and the dioptric power in the vertical meridian is measured by moving the target 53 as described hereinbefore, the lens supporting device is first angled 5 to the right side of the axis I35. This will cause the image or the vertical line 56 of the target 53 to be located to the right side of the vertical hairline SI of the reticule 30. At this time the knob I21 is rotated by the operator to cause the telescope 22 and lens 13 to be moved about the axis of the pivot member 15 an extent suflicient to again align the image of the line 55 with hairline 3|. The indicator device I39 is then set at zero. The lens supporting device 23 is then moved to the setting of 5 on the opposite side of the axis I36. This will cause the image of the line 56 to move to the left of the hairline 3|. The knob I21 is again rotated to realign the image of the line 56 with hairline 3i, and the resultant reading on the indicator device gives the per cent magnification of the lens 13 in the meridian under test. It is to be understood that the angular displacement of the lens and the effective length of the arm IZI are so controlled asto enable the dial gauge t9 directly indicate the adjustments, as accomplished by rotation of the knob I21, in per cent magnification.

In order to find the magnification of the lens 13 in the opposite major meridian, the lens 13 in the supporting structure 23 must be rotated 90 with respect to its first position as described hereinbefore. The vertical image line 55 must be again brought into focus by moving the target 53, which gives the dioptric power of the lens in said meridian on the scale 58; Then by repeating the operations described in the preceding paragraph the per cent magnification of the lens 13 in the said opposite meridian can be determined; I

. While the above enables the determinationof the dioptric power and shape magnification of the lens independently of magnification due to power 'in the major meridians of the lens and thereby enables one to accurately determine dioptric power and shape magnification of prescriptive lensesas when supported in a predetermined fixed standard established position before the eyes, it might be desirable, in instances when the prescriptive lenses are going to be supported at a position other than standard, to know what the'eifective dioptric power and total magnification of the lens will be at said position. v I

In'orcler to measurethe effective dioptric power and total magnification at said different positions, the instrument embodying the invention is provided with a scale I41 mounted on 'the'upper surface of the plate 14, see Figs. land 2. This scale I41 is graduated in millimeters as diagrammatically illustrated at I48 and functions cooperative with an indicator line I49 positioned on the'side of the block "which is slideably mounted in the plate 14 as previously described above. The scale I51 is provided with longitudinal slots I59 and I5I' adjace'nt the opposed ends thereof and is 10* a screw I52 extending through the slot I5!) and a thumb screw I53. which extends through the slot I51.

In making such measurements, the lens under test held by the lens-holding mechanism of the device as previously described above, after having its optical center properly aligned with the optical axis of the instrument, is first moved to position the apex of its rear surface into engagement with the end IIl'I which establishes the initial reference point or normal standard wearing distance. The scale I41 is then moved with respect to the plate 14, by first loosening the thumb screw I53 to position the zero scale line thereon in alignment with the reference line I43. The scale is then looked in position by tightening the thumb screw I53 and the block 11 carrying the lens supporting mechanism is then moved longitudinally of the slideway in the plate 14 a controlled amount as determined by the scale I41 in accordance with the position at which the lens is to be actually supported before the eyes. This adjustment is equal to that of the ofi position of the lens from the normal standard established distance. The effective dioptric power is then determined in a manner similar to that described above and the magnification factors of the lens is determined in a manner similar to that described above in determining shape magnification. However, the magnification reading, as obtained from the indicating device I30 will now give shape magnification plus power magnification as introduced by the off position of the apex of the rear surface of the lens from that of the normal distance.

From the foregoing description, it will be seen that simple, efficient, and economical means have been provided for accomplishing all of the objects and advantages of the invention.

It is pointed out that all of the operative parts of the instrument are self-contained in a device which is conveyable and which will occupy a minimum amount of space.

While the novel features of the invention have been shown and described and are pointed out in the annexed claims, it will be understood that various omissions, substitutions, and changes in the invention and widely different embodiments of the invention can be made without departing from the scope thereof, and it is intended that allmatters contained in the above description and shown in the accompanying drawing be interpreted as illustrative and not in a limiting sense.

I claim:

1. An instrument of the character described comprising a support, viewing means having a reticule mounted on said support, target means mounted on said support and embodying imageforming means normally positioned-substantially in axial alignment with the optical axis of the instrument, means for illuminating said target means, means for directing light rays from said illuminated target means along said optical axis to render an image thereof visible in the plane of the reticule, supporting means on said support for holding'a lens system to be tested between said reticule and target and in the path of the light'rays at a position so'rel'ated with said target as to prevent any change of said rays due to the power of said lens system, means for independently adjusting said supporting means and lens system to given angular positions on the opposite sides of said optical axis to cause the light rays to adjustably secured to the plate 14 by means of be displaced controlled amounts on said opposite ides according to the optical characteristics of the lens system under test, said means comprising a plate member on which said supporting means is mounted, a pivot member carried by said support and having said plate member attached thereto, and locating means on said support and plate for retaining said plate and supporting means in desired adjusted position with respect to the axis of said pivot member, said plate member having slideways formed therein for slidable reception of said supporting means, and said target means having adjustable stop means thereon for engagement by said lens system to be tested whereby said lens system to be tested may be adjusted to a predetermined position with respect to said target means, adjustment means for moving the reticule and image of the target into aligned relation with each other while viewing said reticule and image through the lens system under test at said respective angular positions, and indicating means for determining the range of adjustment required to bring about said alignments.

2. An instrument of the character described comprising a support, viewing means having a reticule mounted on said support, target means mounted on said support and embodying imageiorming means normally positioned substantially in axial alignment with the optical axis of the instrument, means for illuminating said target means, means for directing light rays, from said illuminated target means along said optical axis to render an image thereof visible in the plane of the reticule, supporting means on said support for holding a lens system to. be tested between said reticule and target and in the path of the light rays at a position so, related with said. target as to prevent any change of said rays due to the power of said lens. system, means for independently adjusting said supporting means and lens system to given angular positions on the opposite sides of said optical axis to cause the light rays to be displaced controlled amounts on said opposite sides according to. the optical characteristics of the lens system under test, said. means comprising a plate member on which said supporting means is mounted, a pivot member carried by said support and having said plate member attached thereto, the axis of said pivot member intersecting the axis of said. target. means, and locating means on said support and plate for retaining said plate and. supporting means in desired adjusted position with respect to the axis.

of said pivot member, said plate member having slideways formed therein for slidable reception or" said supporting means, and said target means having adjustable stop means thereon for en.- gagement by said lens system to be tested whereby said lens system to be tested may be adjusted to a predetermined position where the apex of the surface thereof directed toward said target means will be positioned substantially on said optical axis at the point of intersection by the axis of said pivot member, adjustment. means for moving the reticule and image of the target into aligned relation with each other while viewing said reticule and image through the lens system under test at said respective angular positions, and indicating means for determining the range of adjustment required to bring about said alignments.

3. An instrument of. the character described comprising a base, a supportmounted on said base for adjustment. about a. pivotwhose a is tersects the optical axis of the instrument at ap- 12 proximately right angles, viewing means having a reticule mounted on said support to one side of said pivot and target means mounted on saidbase on the other side of the pivot and embodying image-forming means normally positioned substantially in axial alignment with the optical axis of the instrument, means for illuminating said target means, means for directing light rays from said illuminated target means along said optical axis to render an image thereof visible in the plane of the reticule, supporting means adjustably mounted on said support for movement about the axis of said pivot and having means holding a lens system to be tested between said reticule and target and in the path of the light rays at a position adjacent the axis of said pivot and so related with said target as to prevent any change of said rays due to the power of said lens system, said supporting means comprising an upright having lens holding means thereon, said holding means being rotatable in said upright for permitting said lens system to. be tested to be rotated substantially about the said optical axis in order to determine. optical characteristics thereof in various meridians and. embodying indicating means for registering th adjustment of said holding means in said upright, means for independently adjusting said supporting means and lens system about said axis of the pivot to given angular positions on the opposite sides of said optical axis. to cause the light rays to be displaced controlled amounts on said opposite sides according to the optical characteristics of the lens system under test, and means for retaining said supporting means on the support in said adjusted position, adjustment means for moving the support to bring the reticule and image of the target into aligned relation with each other while holding the lens system under test at said respective angular positions on the support. comprising control means operatively connected to a portion of said support. for permitting adjustment of said support about said pivot, and indicating means operatively attached to said support for registering the range of adjustment required of said support and consequently of said lens system to be tested to bring about said alignments.

4. An instrument of the. character described.

comprising a base, a support mounted on said base, viewing means having a reticule mounted on said support, target means mounted on said base and embodying image-forming means normally positioned substantially inv axial alignment with the optical axis of the instrument, means for illuminating said tar-get means, means for directing light rays from said illuminated target means along said optical axis to render an image thereof visible in. the plane of. the reticule, supporting means mounted on said support for hold.- ing a lens system to be tested between said reticule and target and in the path of the light rays at'a position so. related with said target as to. prevent any change of said rays due to the power of said lens system, means for independently adjusting said supporting means and lens system to given angular positions on the opposite sides of said optical axis to cause. the light. rays to be displaced. controlled amounts on said opposite sidesv according to the optical characteristics of. the lens system under test, said means comprising a. plate member on which said supporting means is mounted, a pivot membercarried by said support and having, said plate; member attached thereto, the axis of said pivot member intersecting the 13 axis of said target means, and locating means on said support and plate for retaining said plate and supporting means in desired adjusted position with respect to the axis of said pivot memsition where the apex of the surface thereof directed toward said target means will be positioned substantially on said optical axis at the point of intersection by the axis of said pivot member, said support being mounted on the base for movement about the axis of said pivot member whereby the reticule and image of the target may be brought into aligned relation with each other while viewing said reticule and image through the lens system under test at said respective angular positions, control means operatively connected to a portion of said adjustable support for permitting adjustment of said support'about the axis of said pivot member, and indicating means operatively attached to said support for registering the range of adjustment required for said support and consequently of said lens system to be tested tobring about said alignments.

5. An instrument of the character described comprising base, a support mounted on said base, viewing means having a reticule mounted on said support, target means mounted on said base and embodying image-forming means normally positioned substantially in axial alignment with the optical axis of the instrument and movable longitudinally of said optical axis whereby it may be properly focussed for viewing through said viewing means, means for illuminating said target means, means for directing light rays from said illuminated target means alongsaid optical axis to render an image thereof visible in the plane of the reticule, supporting means on said support for holding a lens system to be tested between said reticule and target and in the path of the light rays, means for independently adjusting said supporting means and lens system'to given angular positions on the opposite sides of said optical axis to cause the light rays to be displaced controlled amounts on said opposite sides according to the optical characteristics of the lens system under test, said means comprising a plate member on which said supporting means is mounted, a pivot member carried by said support and having said plate member attached thereto, the axis of said pivot member intersecting the axis of said target means, and locating means on said support and plate for retaining said plate 7 and supporting means in desired adjusted posiintersection by the axis of said pivot member, said support being mounted for adjustment about the axis of said pivot member whereby the reticule and image of the targetmay be brought into aligned relation with each other while viewing said reticule and image through the lens system under test at said respective angular positions,

14 and indicating means for determining the range of adjustment required to bring about said alignments.

6. An instrument of the character described comprising a base, a support mounted on said base for adjustment about an axis intersecting the optical axis of the instrument, viewing means having a reticule mounted on said support, target means mounted on said base and embodying image-forming means normally positioned substantially in axial alignment with the optical axis of the instrument and movable longitudinally of said optical axis whereby it may be properly iocussed for viewing through said viewing means, means for illuminating said target means, means for directing light rays from said illuminated target means along said optical axis to render an image thereof visible in the plane of the reticule, supporting means on said support for holding a lens system to be tested between said reticule and target and in the path of th light rays, said supporting means comprising an upright having.

holding means thereon, said holding means embodying fixed lens-engaging means for engagement with one side of said lens system to be tested and yieldable engaging means for engagement with the opposed side of the lens system to be tested, said holding means being rotatable in said upright for permitting said lens system to be tested to be rotated substantially about the said optical axis in order to determine optical characteristics thereof in various meridians and embodying indicating means for registering the adjustment of said holding means in said upright, means for independently adjusting said supporting means and lens system to given angular positions on the opposite sides of said optical axis to cause the light rays to be displaced controlled amounts on said opposite sides according to the optical characteristics of the lens system under test, means for retaining the supporting means in its adjusted position on said support, adjustment means for moving the support to bring the reticule and image of the target into aligned relation with each other while holding the lens system under test at said respective angular positions comprising control means carried by the base and operatively connected to a portion of said support for permitting adjustment of said support, and indicating means operatively attached to said support for registering the range of adjustment required of said support and consequently of said lens system to be tested to bring about said alignments.

'7. An instrument of the character described comprising abase, a support mounted on the base, viewing means having a reticule mounted on said support, target means mounted on said base and embodying image-forming means normally positioned substantially in axial alignment with the optical axis of the instrument and movable longitudinally of said optical axis whereby it may be properly fooussed for viewing through said viewing means, means for illuminating said target means, means for directing light rays from said illuminated target means along said optical axis to render an image thereof visible in the plane of the reticule, supporting means on said support I for holding a lens system to be tested between to be tested and yieldable engaging means for amazes 1'5" engagement with the opposed side of the lens system to be tested, said holding means being rota-table in said upright for permitting said lens system to be tested to be rotated substantially about the said optical axis in order to determine optical characteristics thereof in various meridians and embodying indicating means for registering the adjustment of said holding means in said upright, means for independently adjusting, said supporting means and lens system to given angular positions on the opposite sides of said optical axis to cause the light rays to be displaced controlled amounts on said opposite sides according to the optical characteristics of I the lens system under test, said means comprising a plate member on which said supporting means is mounted, a pivot member carried by said support and having said plate member attached thereto, the axis of said pivot member intersecting the optical axis of said instrument, and locat ing means on said support and plate for retaining said plate and supporting means in desired adjusted position with respect to the axis of said pivot member, said plate member having slideways formed therein for slidable reception of said supporting means, and said target means having adjustable stop means thereon .for engagement by said lens system to be tested whereby said lens system to be. tested may be adjust-ed to a predetermined position where the apex of the surface thereof directed toward said target means will be positionedsubstantially on said optical axis at the point of intersection by the axis of said pivot member, said support being mounted on the base for adjustment about the axis of the pivot member whereby the reticule and image of the target means may be brought into aligned relation with each other While viewing said reticule and image through the lenssystem under test at said respective angular positions, control means carried by the base and operativel connected to a portion of said supportfor permitting adjustment of said support about the axis of said pivot member, and indicating means carried by the base and operatively attached to said support for registering the range of adjustment required of said support and consequently of said lens system to be tested to bring about said alignments.

References. Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,047,000 DeZeng Dec. 10, 1912 2,042,565 Tillyer June 2, 1936 2,107,553 'Till-yer Feb. 8, 1938 2 ,114,282 Ames, Jr. et a1 Apr. 19, 1938 

